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Power- and low-resistance-state-dependent, bipolar reset-switching transitions in sin-based resistive random-access memory

Cited 19 time in Web of Science Cited 19 time in Scopus
Authors

Kim, Sungjun; Park, Byung-Gook

Issue Date
2016-08
Publisher
Springer Verlag
Citation
Nanoscale Research Letters, Vol.11, p. 360
Abstract
A study on the bipolar-resistive switching of an Ni/SiN/Si-based resistive random-access memory (RRAM) device shows that the influences of the reset power and the resistance value of the low-resistance state (LRS) on the reset-switching transitions are strong. For a low LRS with a large conducting path, the sharp reset switching, which requires a high reset power (> 7 mW), was observed, whereas for a high LRS with small multiple-conducting paths, the step-by-step reset switching with a low reset power (< 7 mW) was observed. The attainment of higher nonlinear current-voltage (I-V) characteristics in terms of the step-by-step reset switching is due to the steep current-increased region of the trap-controlled space charge-limited current (SCLC) model. A multilevel cell (MLC) operation, for which the reset stop voltage (V-STOP) is used in the DC sweep mode and an incremental amplitude is used in the pulse mode for the step-by-step reset switching, is demonstrated here. The results of the present study suggest that well-controlled conducting paths in a SiN-based RRAM device, which are not too strong and not too weak, offer considerable potential for the realization of low-power and high-density crossbar-array applications.
ISSN
1931-7573
Language
English
URI
https://hdl.handle.net/10371/139007
DOI
https://doi.org/10.1186/s11671-016-1572-9
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